A Brief Summary for Exam 2Subject Topics
• Number theory (sections 2.4 - 2.5)– Prime numbers
• Definition • Relative prime• Fundamental theorem of arithmetic (unique prime factorization of
integers)– Division
• Definition (a | b iff b = a*c) and properties• Division algorithm: a = dq + r• Modula operation (a mod d)
– gcd and lcm• Their definitions• gcd(a, b)*lcm(a, b) = a*b (why?)• Euclidean algorithm for gcd (both iterative and recursive
• Mathematical Induction & Recursion (sections 3.1 - 3.5)– Sequence and summation
• Definition of sequence (ordered list of elements)• Summation notations (lower/upper limits, double summation)• Useful sequences (arithmetic, geometric, Fibonacci, etc.) and
their summation formulas– Induction
• Rationale and relation to natural numbers• Two parts of the proof
basis step, inductive step (start with inductive hypothesis)• Strong induction• Structural induction
– Recursion• Basic idea of recursion• Recursive definition of
– Sequences, functions, sets– Two parts: base case and recursion
• Relations to inductionprove recursively defined properties by induction
• Recursive algorithms– Pros and cons (wrt iterative algorithms)
• Counting (sections 4.1 – 4.5)– Useful rules:
• Sum rule: (disjoint) tasks done at same time |A1 A2| = |A1| + |A2|
• Product rule: (disjoint) tasks done at different time |A1 A2| = |A1| * |A2|
• Inclusion – exclusion rule: (overlapping) tasks done at same time |A1 A2| = |A1| + |A2| - |A1 A2|
– Pigeonhole Principle• Idea and rationale • at least one box containing at least N/k of the
objects.
– Permutations and combinations• Definitions of permutations, r-permutations, r-
combinations• Formulae for (P(n,n), P(n, r), and C(n, r)
P(n, r) = n!/(n – r)!C(n, r) = n!/[r!(n-r)!]
• Relationship between permutation and combinationsP(n, r) = C(n, r)P(r, r)
• Pascal triangle and Binomial coefficients
• Discrete Probability (sections 5.1 - 5.2)– Experiments, outcomes, and sample space
• Use counting techniques to determine sample space• p(s) for each sS
– 0 p(s) 1 for each sS sS p(s) = 1– If all outcome are equally probable, then p(s) = 1/|S|
– Events and event probability• E S, P(E) = sE p(s) (P(E) = |E|/|S| if outcomes are
equally likely)• Use counting techniques to determine samples in E• Complementary event: P(E) = 1 – P(-E).
– Help with Venn diagram
– Conditional probability P(E|F)• Definition: probability of E, given F (probability
of E or in subspace F S)• Relation to joint probability
– p(E|F) = p(EF)/p(F) or p(E|F) = |EF|/|F| – p(EF) = p(E|F)P(F) = p(F|E)P(E)
– Inclusion-exclusion rule:p(EF) = p(E) + p(F) – p(EF)
– Bayes’ theorem p(F|E) = p(E|F)p(F)/p(E)
– Independence• Events E and F are independent of each other if
p(E|F) = p(E) (E’s probability not depending on F)• P(EF) = p(E) + p(F) –p(E)p(F)
– Bernoulli Trials• Experiment with two outcomes, s and f, • p = P(s), q = P(f) = 1– p (because p + q = 1)• n independent trials with k s (and n – k f)
C(n, k)pkqn-k
Types of Questions• Conceptual
– Definitions of terms
– True/false
– Multiple choice
• Problem solving– Work with small concrete example problems
• Proofs– Simple theorems or propositions
– Especially proof by mathematical induction
No questions will be outside of this summary and lecture notes
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